JP2005323019A - Booster antenna for rfid tag - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a booster antenna for an RFID tag that can increase the communication distance between a reader and the RFID tag. <P>SOLUTION: On a nearly center axis in a space wherein an antenna of the reader and an antenna of the RFID tag are opposed to each other, the booster antenna tuned to a carrier frequency that the RFID tag system uses is arranged in front of the RFID tag opposite the antenna of the reader. Alternatively, on the nearly center axis in the space wherein the antenna of the reader and the antenna of the RFID tag are opposed to each other, the booster antenna tuned to the carrier frequency that the RFID tag system uses is arranged in front of the RFID tag on an almost same surface opposite the antenna of the reader. The booster antenna is composed of a square type or round type loop antenna etc., larger than the antenna of the RF ID tag and a tuning capacitor. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an RFID tag booster antenna for extending a communication distance between a reader called an interrogator and an RFID tag called a responder in an RFID (Radio Frequency Identification) tag system.

  In recent years, automatic recognition by individual ID identification has been widely used in many fields such as service industry, manufacturing industry, distribution industry, sales industry, and logistics. As a means for identifying the ID, a barcode system has been generally used. However, in order to compensate for the shortcomings such as low information storage capacity and inability to rewrite information, the RFID tag system has been attracting attention and is becoming popular. is there. Note that the RFID tag has names such as an electronic tag, a wireless tag, and an IC tag.

  As a communication method of the RFID tag system, data transmission is performed by inductive coupling of each antenna of the interrogator and the responder in a frequency band where the carrier frequency is lower than the microwave. The responder receives power supply from the interrogator as a passive element, and operates the IC in the RFID tag with the power. For example, in an RFID tag system using a carrier frequency such as 4.915 MHz or 13.56 MHz, a carrier transmitted from an antenna on the interrogator side is received by the antenna on the transponder side, and the magnetic field or electromagnetic field is inductively coupled. Since the induced electromotive force generated in the antenna is rectified and smoothed to obtain an IC power supply, the responder side can operate without a battery. That is, it can be said that the inductive coupling by the interrogator and the responder constitutes a transformer through a space.

  As the communication distance of the RFID tag system, a close contact type (international standard: ISO / IEC10536) of several millimeters, a proximity type of about several cm to 10 cm (international standard: ISO / IEC14443), and a proximity type of about 50 cm to 1 m. (International standard: ISO / IEC15693). The carrier frequency is generally 4.915 MHz for the contact type and 13.56 MHz for the proximity type and the proximity type.

  The contact type, proximity type, and proximity type RFID tag systems are used in applications adapted to each communication distance, but have a communication distance of 1 m or more, preferably about 3 m, or a batteryless RDID tag system. Therefore, when the transmission power on the interrogator side is made constant, it has been desired to expand applications by increasing the reception sensitivity on the responder side and extending the communication distance.

In order to solve the above-mentioned object, it is necessary to increase the area and increase the directivity of the antenna on the responder side, and to improve the power supply capability at a distance. For this reason, in Japanese Patent Laid-Open No. 2002-151947, a director and a reflector are provided on the antenna on the responder side to enhance the directivity as an antenna structure of the Yagi antenna shape. It is disclosed that a large loop antenna is provided on the outer periphery of the antenna to relatively increase the area of the antenna.
JP 2002-151947 A JP 2003-249813 A RFID handbook, written by Klaus Finkenzeller, translated by Institute of Software Engineering, published by Nikkan Kogyo Shimbun

  However, the former example has a structure in which a plurality of waveguides are arranged at the front stage part of the antenna connected to the IC of the RFID tag and a reflector is arranged at the rear stage part, and the area of the antenna itself is not large. This method seems to be effective for microwaves with a carrier frequency of 2.45 GHz, etc., but in a system that supplies power to the responder side by inductive coupling using a magnetic field or electromagnetic field, the power is not supplied because the antenna area is small. There is a drawback of not being able to do enough. In the latter case, the loop antenna of 10 cm square to 30 cm square is arranged on the outer periphery of the same surface as the RFID tag, and is intended to be installed on a road surface or a wall surface. Although this method increases the area of the antenna, the RFID tag itself also increases, and there is a drawback that the application is limited.

  The present invention has been made to solve the above-described drawbacks. The power supply capability and directivity are improved without increasing the antenna of the RFID tag itself, and the communication distance between the reader and the RFID tag is reduced. An object of the present invention is to provide a booster antenna for an RFID tag that can be extended.

  In order to solve the above-described problems, in the RFID tag booster antenna of the present invention, the reader antenna that is the interrogator and the antenna of the RFID tag that is the responder are positioned in front of the RFID tag on a substantially central axis in a space facing each other. A booster antenna tuned to the carrier frequency used in the RFID tag system is placed facing the reader antenna.

  Or, the carrier frequency used in the RFID tag system in front of and substantially on the same plane of the RFID tag on the substantially central axis in the space where the antenna of the reader as the interrogator and the antenna of the RFID tag as the responder face each other. A tuned booster antenna is placed facing the reader antenna.

  The booster antenna includes a loop antenna having a square shape or a round shape larger than the antenna of the RFID tag and a tuning capacitor.

  The booster antenna of the present invention is radiated from the reader antenna by arranging the booster antenna in front of the RFID tag on a substantially central axis in a space where the reader antenna and the RFID tag antenna face each other, or in front and substantially on the same plane. The magnetic field can be efficiently induced by mutual induction. Further, since the booster antenna circuit is tuned to the carrier frequency, the magnetic field becomes dense and the power supply capability to the RDID tag increases. For this reason, even if the antenna of the RFID tag itself is not enlarged, the area of the antenna becomes relatively large and the directivity is improved, and the communication distance between the reader and the RFID tag can be greatly extended. Has a great effect.

  The best mode for carrying out the present invention will be described with reference to the drawings. FIG. 1 is an arrangement schematic diagram of an RFID tag booster antenna according to the present invention, and FIG. 6 is a diagram in which a booster antenna is arranged on substantially the same surface as the RFID tag in FIG.

  As shown in FIG. 1, the antenna 4 of the reader 3 as an interrogator and the antenna 2 of the RFID tag 1 as a responder are located at a position of a distance L slightly in front of the RFID tag 1 on a substantially central axis. A booster antenna 5 tuned to a carrier frequency used in the RFID tag system, for example, 4.915 MHz or 13.56 MHz is disposed so as to face the antenna 4 of the reader 3. Further, as shown in FIG. 6, a distance L slightly in front of the RFID tag 1 on a substantially central axis in a space where the antenna 4 of the reader 3 as an interrogator and the antenna 2 of the RFID tag 1 as a responder face each other. The booster antennas 5 and 5 ′ that are tuned to the carrier frequency used in the RFID tag system are arranged to face the antenna 4 of the reader 3 at both the position and substantially the same plane as the RFID tag 1. The antenna 4 of the reader 3, the antenna 2 of the RFID tag 1, and the booster antennas 5 and 5 ′ are arranged in parallel so that the antenna surfaces face each other on a substantially central axis. This is preferable from the viewpoint of supplying power to the IC in the RFID tag 2. In the above-described two embodiments, when the latter booster antenna 5 and booster antenna 5 ′ are arranged, mutual induction becomes larger and the communication distance is extended compared to the case where only the former booster antenna 5 is arranged. Becomes more effective.

  FIG. 2 is a configuration circuit diagram of a booster antenna for an RFID tag according to the present invention. The booster antenna 5 includes a loop antenna 6 and a tuning capacitor 7 that are larger than the antenna 2 of the RFID tag 1. The loop antenna 6 has a rectangular shape, but may have another shape such as a round shape depending on the application. Further, the size of the loop antenna 6 and the distance L from the RFID tag 1 may be arbitrarily set according to the system to be used.

  As a manufacturing means, a loop antenna 6 is wound on a substrate with a copper wire or a copper foil is etched to pattern the loop antenna 6 on the substrate, and a single chip capacitor and / or trimmer capacitor is formed on the tuning capacitor 7. It is manufactured by soldering. The tuning capacitor 7 may also be a pattern formed by etching. Note that any material may be used for the substrate.

  FIG. 3 is an operation principle diagram of the RFID tag booster antenna of the present invention. When the reader 3 performs data transmission with the RFID tag 1, the antenna 4 of the reader 3 outputs a modulation signal in which data is superimposed on a carrier. . The modulation signal is generated as a magnetic field and is radiated from the antenna 4 which is a loop antenna. At this time, the magnetic field 8 in the vicinity of the antenna 4 is dense, and the magnetic field 8 'in the distance is coarse. The booster antenna 5 disposed just in front of the RFID tag 1 can efficiently induce the rough magnetic field 8 'by mutual induction because the booster antenna circuit is tuned to the carrier frequency of the modulation signal. For this reason, the booster antenna 5 is resonated by the magnetic field 8 ′, and an increased magnetic field 9 is generated. Since the magnetic field 9 is the same modulation signal as the original magnetic field 8, the power supply capability of the RDID tag 1 to the antenna 2 is improved and the communication distance is extended.

In principle, the induced electromotive force generated by mutual induction is obtained. FIG. 7 is a diagram showing conditions for obtaining the mutual inductance M acting between two coils. Here, the antenna 4 of the reader 3 is a round loop antenna, the radius is a (m), the antenna 2 of the RFID tag 1 is also a round loop antenna, the radius is b (m), and the distance between the two antennas. Where d (m) is the mutual inductance M acting between the two coils. Note that μ ₀ is the magnetic permeability in vacuum, N ₁ is the number of turns of the antenna 4 of the reader 3, and N ₂ is the number of turns of the antenna 2 of the FID tag 1.

Therefore, the electromotive force e ₁ induced in the antenna 2 of the RFID tag 1 by the resonance current i ₂ flowing in the antenna 4 of the reader 3 is expressed by the following equation (2). The electromotive force e ₁ is an absolute value regardless of positive or negative.

  In the present invention, since the booster antenna 5 is arranged in front of the RFID tag 1 or the booster antenna 5 ′ is arranged in front of the RFID tag 1 and substantially in the same plane, mutual inductances by the booster antennas 5 and 5 ′ are added. Therefore, the electromotive force is increased, and the power supply capability to the RFID tag 1 is improved.

  Embodiments of the present invention will be described with reference to the drawings. FIG. 4 is a diagram showing an embodiment of an RFID tag booster antenna according to the present invention.

  In this figure, the ID information of the RFID tag 1 attached to a plurality of products 12 in the cabinet 10 is read by an external reader (not shown). Since the proximity type RFID tag system has a communication distance of about 50 cm to 1 m, ID information can be read by holding the reader antenna slightly forward of the cabinet 10, but the cabinet 10 or the product 12 is relatively large. If it is desired to read ID information from a remote location, it is necessary to extend the communication distance. For this reason, it becomes possible to extend the communication distance by arranging the booster antenna 5 composed of the loop antenna 6 and the tuning capacitor 7 on the outer peripheral portion of the door 11 of the cabinet 10, and the cabinet 10 or the product 12 is relatively large. Even when it is desired to read ID information from a remote location, the ID information can be read.

  The RFID tag 1 affixed to the product 12 in the cabinet 10 in the above embodiment needs to be basically arranged parallel to the booster antenna 5, but may actually be arranged vertically. FIG. 5 shows a diagram in which booster antennas are arranged on the other surface in FIG. 4, and copes with such a case.

  In the figure, in a cabinet 10, a product 12 having a booster antenna 5 and an RFID tag 1 attached in a parallel direction and a product 12 'having a booster antenna 5 and an RFID tag 1' attached in a vertical direction are mixed. . For this reason, by arranging the booster antenna 5 on the outer peripheral portion of the door 11 of the cabinet 10 and also arranging the booster antenna 5 on the outer peripheral portion of the upper surface, the booster antennas 5 and 5 are inductively coupled and are affixed to the product 12. Both the ID information of the RFID tag 1 and the ID information of the RFID tag 1 ′ attached to the product 12 ′ can be read.

  In addition, although the said Example is based on the arrangement example of the booster antenna shown in FIG. 1, in order to implement the arrangement example of the booster antenna shown in FIG. Or by arranging the booster antenna 5 ′ on the outer periphery of the same surface of the RDID tag 1, 1 ′ attached to the product 12, 12 ′.

  In the description of the above embodiment, an example of reading the ID information of the RFID tag attached to the product in the cabinet is shown. However, for example, a booster antenna is embedded in the outer peripheral portion of the bag, The present invention can be applied to any RFID tag system such as a system for reading ID information of an RFID tag attached to a product.

It is an arrangement schematic diagram of the booster antenna for RFID tags of the present invention. It is a circuit diagram of a booster antenna for an RFID tag according to the present invention. It is an operation | movement principle figure of the booster antenna for RFID tags of this invention. It is a use example figure of the booster antenna for RFID tags of the present invention. It is the figure which has arrange | positioned the booster antenna also in the other surface in FIG. FIG. 2 is a diagram in which booster antennas are arranged on substantially the same surface as the RFID tag in FIG. 1. It is a figure showing the conditions for calculating | requiring the mutual inductance M which acts between two coils.

Explanation of symbols

1 RFID Tag 2 Antenna 3 Reader 4 Antenna 5 Booster Antenna 6 Loop Antenna 7 Tuning Capacitor 8 Magnetic Field 9 Magnetic Field 10 Cabinet 11 Door 12 Product

Claims (3)

  A booster antenna tuned to the carrier frequency used in the RFID tag system is placed in front of the RFID tag on a substantially central axis in a space where the antenna of the reader that is the interrogator and the antenna of the RFID tag that is the responder face each other. A booster antenna for an RFID tag, characterized in that it is placed facing the antenna of the RFID tag.   The antenna of the reader, which is the interrogator, and the antenna of the RFID tag, which is the responder, are tuned to the carrier frequency used in the RFID tag system in the front and substantially on the same plane on the substantially central axis. A booster antenna for an RFID tag, wherein the booster antenna is arranged to face a reader antenna.   The booster antenna for an RFID tag according to claim 1 or 2, wherein the booster antenna includes a loop antenna having a square shape or a round shape larger than an antenna of the RFID tag and a tuning capacitor.

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